KR100333213B1 - Soft tissue paper having a surface deposited softening agent - Google Patents

Abstract

The present invention discloses a strong, soft, low dust tissue paper web useful for the production of soft, absorbent hygiene products such as bath tissues, cosmetic tissues, and absorbent towels. At least one surface of such tissue paper has a uniform discontinuous surface deposit of a chemical softener that is substantially fixed.

Description

SOFT TISSUE PAPER HAVING A SURFACE DEPOSITED SOFTENING AGENT

Sanitary paper tissue products are widely used. Such products are commercially available in a form adapted for a variety of uses such as cosmetic tissues, toilet paper and absorbent towels.

These hygiene products all share the public need to be soft, especially at the time of contact. Softness is the complex touch caused by the hygiene article when it comes into contact with the skin. The goal is to be gentle because it should be possible to clean the skin without irritation with these hygiene products. Effective skin cleansing is a permanent personal hygiene issue for many. Unpleasant excretion such as urine, menstrual blood and manure or otolaryngological mucus excretion released from the perineum cannot always be thoroughly cleaned at a time convenient for a person, for example, with soap and abundant amounts of water. As an alternative for thorough cleaning, a wide variety of tissue and towel products are provided to assist in the removal and retention of the above mentioned excretion from the skin in a sanitary manner. Typically, such products cannot be used to reach the level of cleanliness that can be achieved by more thorough cleaning methods, and manufacturers of tissue and towel products seek to produce such products that can be more advantageously compared to thorough cleaning methods. I'm trying hard.

A drawback with tissue products is the fact that in many cases, for example, the skin must be stopped before the skin is completely cleaned. This behavior is facilitated by the tissue's harshness, as rubbing the skin with a rough tool can cause sensitive skin to come off and cause severe pain. Running, sometimes odors and stains in the undergarment, and may cause irritation to the skin over time, you should choose another method of partial cleansing of the skin.

Anal disorders, such as hemorrhoids, make the perineum extremely sensitive and those who suffer from these disorders are frustrated by the need to clean the anus without irritation.

A remarkable case of frustration is the need to repeatedly blow your nose when you have a cold. Even with the softest tissues available on the market today, repeated nose-blowing and wiping can hurt your nose.

Thus, the manufacture of soft tissue and towel products that can be comfortably cleaned without compromising performance has long been a goal of engineers and scientists dedicated to research to improve tissue paper. Many attempts have been made to reduce the wear effect of tissue products, i.e. to improve the flexibility of tissue products.

One area that has been developed in this regard has been to select and modify cellulose fiber forms and engineering paper structures to optimize the benefits of various useful forms. Examples of techniques applicable in this field include U.S. Patent Nos. 5,228,954, issued to Vinson et al. On July 20, 1993, and U.S. Patents 5,405,499 and 1989, issued to Vinson on April 11, 1995. US Patent No. 4,874,465, issued to Cochrane et al. On October 17, 2013, all of which disclose a method of selecting or improving a fiber source to impart super-strong properties to tissues and towels. . Applicable techniques are also illustrated in US Pat. No. 4,300,981 issued to Carstens on November 17, 1981, which describes how fibers can be incorporated to conform to paper structures so that they have the highest flexibility. It is. While these techniques, as exemplified in these prior art documents, are widely recognized, these techniques can only offer some limited possibilities for making tissues using very effective comfortable cleaning devices.

Another technical field that has received considerable attention has been the addition of chemical softening agents (also referred to herein as 'chemical softeners') to tissue and towel products.

As used herein, the term 'chemical softening agent' refers to certain chemical ingredients that improve the tactile sensation perceived by consumers who have a particular paper product and scrub the skin with it. Although sometimes desirable for towel products, flexibility is a particularly important property for cosmetic tissues and toilet paper. This tactile flexibility is characterized by, but not limited to, friction, flexibility and smoothness as well as subjective feelings such as lubricants, velvets, silks or flannel-like feelings that give the tissue a smooth feel. Examples of these include basic waxes such as paraffin and beeswax and oils such as mineral and silicone oils, as well as more complex lubricants such as petroleum and quaternary ammonium compounds with long chain alkyl chains, functional silicones, fatty acids, fatty alcohols and fatty esters. And softeners, these examples are for illustrative purposes only.

The working area in the prior art, which belongs to chemical softeners, follows two routes. The first route is to add an attractant component to the batt of the pulp that will ultimately form the tissue paper web during the formation of the tissue paper web, or to the wet paper when the pulp slurry approaches the paper machine, or wet When the web is placed on a papermaker's fourdrinier cloth or dryer cloth, it is characterized by adding flexibility to the tissue paper web by adding an attractant component thereto.

The second route is classified as adding a chemical softener to the tissue paper web after it is dried. Applicable processes can be coupled to papermaking operations, for example, by spraying on a dried web prior to winding in a paper roll.

Exemplary techniques relating to the first route, classified as adding chemical emollients to tissue paper prior to assembly into a web, were issued to Phan and Trokhan, issued November 23, 1993, incorporated herein by reference. US Patent No. 5,264,082. This method is widely used industrially, especially when there is a need to reduce the strength that will be present in running paper and when papermaking processes, especially creping, are strong enough to permit the incorporation of binding inhibitors. Turned out. However, there are problems associated with this method that are well known to those skilled in the art. Firstly, it does not control the position of the chemical softener, ie the chemical softener is dispersed as widely as the fiber feed to which it is applied through the paper structure. In addition, the use of such additives results in a loss of paper strength. Without being bound by theory, it is widely believed that such additives inhibit the formation of fiber-fiber hydrogen bonds. Further, the sheet's control may be lost when creping it in a Yankee dryer. Again, a well-known theory is that the additive interferes with the coating on the Yankee dryer, weakening the bond between the wet web and the dryer. Prior art, such as US Pat. No. 5,487,813 to Vinson et al., Issued January 30, 1996, incorporated herein by reference, discloses chemical formulations that deliver the aforementioned effects on strength and adhesion to a creping cylinder. However, however, there is still a need to incorporate chemical emollients into the paper web in an optimal manner with minimal effect on web strength and interference associated with the manufacturing process.

Another exemplary prior art example involving the addition of a chemical softener to a tissue paper web during the formation of the tissue paper web is described in Ampulski et al., Filed Oct. 22, 1991, incorporated herein by reference. Patent No. 5,059,282. The Ampulsky patent discloses a process for adding a polysiloxane compound (preferably at a fiber concentration between about 20% and about 35%) to a wet tissue web. This method represents a slight improvement over the addition of chemicals into the slurry batt supplied to the paper machine. For example, such means aim to apply to one surface of the web surface as opposed to distributing the additive on all the fibers in the feed. However, this method does not overcome the primary disadvantages of adding a chemical softener at the end of the wetting stage of the paper machine, namely the strength effect and the effect on the coating of the Yankee dryer, which must be used.

Due to the above mentioned effects on the strength and cleavage of the papermaking process, many techniques have been devised to apply chemical softeners to already dried paper webs at the end of the so-called drying stage of the paper machine or in a separate conversion operation following the papermaking stage. come. Exemplary techniques in this field are described in U.S. Patent No. 5,215,626 to Ampulsky et al., Dated June 1, 1993; US Patent No. 5,246,545 to Ampulsky et al. On September 21, 1993; And US Pat. No. 5,525,345 to Warner et al. June 11, 1996, all of which are incorporated herein by reference. U. S. Patent No. 5,215, 626 discloses a method of making soft tissue paper by applying polysiloxane to a dry web. U. S. Patent No. 5,246, 545 discloses a similar method using a heated transfer surface. Finally, Warner's patent discloses a coating method comprising roll coating and extrusion for applying a specific composition to the surface of a dry tissue web. The techniques mentioned in each of these references show an improvement over the so-called wet stage end method mentioned above, especially with regard to reducing the deterioration effect on the papermaking process, but the loss of tensile strength accompanying application to dry paper webs. There is no way to solve it completely.

In general, one of the most important physical properties related to the flexibility of experts in the art is the strength of the web. Strength is the ability of the product and the web to construct it to maintain physical integrity under conditions of use and to resist tearing, rupture and shredding. For those skilled in the art, a long goal has been to achieve high flexibility without compromising strength.

Accordingly, it is an object of the present invention to provide a soft tissue paper without loss of performance such as the strength of the paper.

These and other objects are achieved by using the present invention described below.

Summary of the Invention

The present invention relates to a rigid, soft tissue paper product consisting of one or more layers of tissue paper, wherein the at least one outer surface of the product has a uniform, discontinuous surface deposit of a chemical softener that is substantially fixed.

Preferred embodiments of the present invention are characterized by having uniform surface deposits spaced at a frequency of about 5 to about 100 deposits per 2.54 cm (1 inch) in length. Most preferably, the uniform surface deposits are spaced at a frequency of about 7 to about 25 deposits per 2.54 cm in length.

As used herein, the term 'frequency', which refers to the spacing of deposits of chemical softeners, is defined as the number of deposits for a length of 2.54 cm as measured in the closest separation direction. Many patterns or arrangements of deposits are limited to being uniform and discontinuous, and the separation is believed to be measurable in several directions. For example, deposits in a straight array are measured to have less deposits per 2.54 cm in the diagonal direction than on horizontal and vertical lines. We consider the direction of the minimum separation distance to be the most important and thus limit the frequency in that direction. A typical typesetting pattern is a so-called 'hexagonal' pattern in which the concave region is engraved on the center lying in the corner of the equilateral hexagon, and another further concave region lies in the center of the hexagonal shape. The closest separation distance for this arrangement is thought to lie along a pair of lines crossing each other at an angle of 60 ° and along a horizontal line that intersects each at an angle of 60 °. Therefore, the number of cells per square area in the hexagonal arrangement is 1.15 times the square frequency.

The present invention is also characterized by having a uniform surface deposit of a chemical softener predominantly lying on one or both of the two outer surfaces of the soft tissue paper product.

Finally, the present invention is characterized by having a tissue surface protected with less than about 50%, more preferably less than about 25%, and most preferably less than about 5% chemical softener.

Without wishing to be bound by theory, the inventors believe that the combination of geometrical parameters mentioned herein inhibits the surprising maximum response to softened tissue in human touch caused by the spacing of neural sensors on human skin. .

Preferred chemical emollients that are substantially fixed include quaternary ammonium compounds, such as the well-known dialkyldimethylammonium salts (e.g. ditallowdimethylammonium chloride, ditallowdimethylammonium methyl sulfate, di (hydrogenated tallow) dimethylammonium chloride, etc. ), But are not limited to these. Particularly preferred among these softeners are the mono- or diester derivatives of the aforementioned dialkyldimethylammonium salts. Examples of such compounds are diester dietal dimethyl ammonium chloride, diester diesteryl dimethyl ammonium chloride, monoester dielow dimethyl ammonium chloride, diester di (hydrogenated) tallow dimethyl ammonium methyl sulfate, diester di (hydrogenated) Tallow dimethyl ammonium chloride, monoester di (hydrogenated) tallow dimethyl ammonium chloride, and mixtures thereof, among which di (non-hydrogenated) tallow dimethyl ammonium chloride, di (Touch) Particular preference is given to diesters of hydrogenated) tallow dimethyl ammonium chloride (DEDTHTDMAC) and di (hydrogenated) tallow dimethyl ammonium chloride (DEDHTDMAC), and mixtures thereof. Depending on the desired properties of the product, the saturation of the detalow can be adjusted by dehydrogenation (soft), or partially or fully hydrogenation (hard).

If an appropriate plasticizer is used, the quaternary ammonium component described above is most effective. Plasticizers may be added during the quaternization step in the preparation of the quaternary ammonium component, or subsequently added. Plasticizers are characterized by being substantially inert during chemical synthesis but acting as a viscosity reducing agent to aid in synthesis and subsequent handling, ie, application of quaternary ammonium compounds to tissue products. Preferred plasticizers consist of a combination of a nonvolatile polyhydroxy compound and a fatty acid. Preferred polyhydroxy compounds are glycerol and polyethylene glycols having a molecular weight of about 200 to about 2000, with polyethylene glycols having a molecular weight of about 200 to about 600 being particularly preferred. Preferred fatty acids include C ₆ -C ₂₃ linear or branched, saturated or unsaturated analogues, of which isostearic acid is most preferred.

Other embodiments of the preferred chemical emollients that are substantially fixed include organo-reactive polydimethyl siloxane components that are well known, with amino-functional polydimethyl siloxanes being most preferred.

The most preferred form of substantially fixed chemical emollient is a mixture of organo-reactive silicone and a suitable quaternary ammonium compound. In this embodiment, the organo-functional silicone is preferably amino polydimethyl siloxane and is used in an amount ranging from 0 to about 50%, preferably from about 5% to about 15%. The aforementioned percentages represent the weight of polysiloxane which is substantially proportional to the total weight of the softener fixed.

The soft tissue paper of the present invention preferably has a basis weight of about 10 g / m ² to about 50 g / m ² , more preferably about 10 g / m ² to about 30 g / m ² . The soft tissue paper of the present invention has a density of about 0.03 g / cm 3 to about 0.6 g / cm 3, more preferably about 0.1 g / cm 3 to about 0.2 g / cm 3.

The soft tissue paper of the present invention further comprises papermaking fibers of both the hardwood type and the softwood type, wherein at least 50% of the papermaking fibers are hardwood and at least 10% are softwood. Most preferably, the hardwood and softwood fibers are isolated by isolating each into separate layers, wherein the tissue comprises one inner layer and at least one outer layer.

The tissue paper product of the invention is preferably creped, i.e., the tissue paper product of the invention has a Yankee dryer attached to and dried on a partially dried papermaking web and removed therefrom by a flexible crepe blade. It is produced on a paper machine equipped in the last step.

Although the properties of creped paper webs are preferred for carrying out the invention, especially when the creping process is carried out by a pattern densification method, uncreped tissue is also a satisfactory substitute, specifically such crepe unprocessed. The practice of the present invention using tissue paper is also within the scope of the present invention. As used herein, the term uncreped tissue paper most preferably refers to tissue paper that has been dried incompressibly by aeration. The resulting aerated dried web is pattern densified so that relatively dense bands are dispersed in the high volume area containing the pattern dense tissue, where the relatively dense bands are continuous and the high volume areas are discontinuous.

To produce an uncreped tissue paper web, the initial web is moved from the porous molded carrier on which it is placed to a higher fiber support delivery fabric carrier that moves at a slower rate. The web is then delivered onto a dry fabric, where the web is dried to its final dryness. Such webs can provide some advantages in surface smoothness over creped webs.

Techniques for making uncreped tissue in this manner are taught in the prior art. For example, European Patent Application No. 0 677 612 A2 to Wentt et al., Published Oct. 18, 1995, incorporated herein by reference, teaches a method of making a soft tissue product without creping. In other instances, European Patent Application No. 0 617 164 A1, published September 28, 1994 and incorporated herein by reference, teaches a method for making a fully dried smoothed sheet that has not been creped. It is.

Tissue paper webs generally comprise papermaking fibers essentially. Generally it contains small amounts of chemical functionalizing agents such as wet strength or dry strength binders, retention aids, surfactants, agents, chemical emollients, creping facilitation compositions, but typically these components are used in trace amounts. The papermaking fibers most frequently used in tissue paper are pure chemical wood pulp.

The filler may also be incorporated into the tissue paper of the present invention. United States Patent Application Serial No. 08 / 418,990 to Vinson et al., Filed April 7, 1995 and also incorporated herein by reference, discloses a filled tissue paper product that is acceptable as a substrate for the present invention.

The present invention relates generally to tissue paper products and, more particularly, to tissue paper products containing chemical emollients.

1 is a side view of a printing apparatus illustrating a preferred method for forming a uniform surface deposit of a substantially fixed chemical softener of the present invention. The process illustrated in FIG. 1 is a process of applying a softener to one surface of a tissue paper product by an offset printing method.

2 is a side view of a printing apparatus illustrating another method for forming a uniform surface deposit of a substantially fixed chemical softener of the present invention. The process illustrated in FIG. 2 is a process of applying a softener to one surface of a tissue product by direct printing.

3 is a side view of a printing apparatus illustrating another method for forming a uniform surface deposit of a substantially fixed chemical softener of the present invention. The process illustrated in FIG. 3 is a process of applying a softener to both surfaces of a tissue paper product by an offset printing method.

4 is a schematic diagram detailing a concave region for use on the printing cylinder illustrated in FIGS. 1, 2 and 3. 4A illustrates in more detail an exemplary recessed region for use in the present invention by illustrating one of the recessed regions in cross section.

While this specification concludes with the claims particularly pointed out and specifically claimed by the subject matter regarded as the invention, the invention will be better understood from the following detailed description and the appended examples.

The term 'comprising' as used herein means that various components, components or steps may be used together in practicing the present invention. Thus, the term 'comprising of' includes more limited terms such as 'consisting essentially of' or 'consisting of'.

As used herein, the term 'water soluble' refers to a substance that is dissolved at least 3% by weight in water at 25 ℃.

As used herein, the terms 'tissue paper web, paper web, web, paper sheet and paper product' all refer to aqueous paper furnishes. forming a furnish, depositing the furnish on a porous surface such as a Fourdrinier wire, removing water from the furnish by gravity or vacuum-assisted drainage, the initial web Refers to a sheet of paper produced by a process comprising forming a; and transferring the initial web from a forming surface to a transfer surface moving at a slower speed than the forming surface. The web is then delivered to the fabric, dried over it to its final dryness and then wound onto a reel.

'Multi-layered tissue paper webs, multi-layered paper webs, multi-layered webs, multi-layered paper sheets and multi-layer paper products The term " layered paper product " is preferably used in the art to include two or more layers of aqueous, preferably comprising different types of fibers, such as relatively long softwood fibers and relatively short hardwood fibers, typically used in tissue making. All of which are used interchangeably as referring to sheets of paper made from papermaking furnish. The layers are preferably formed by depositing a separate stream of thin fiber slurry on one or more endless porous surfaces. When the individual layers are initially formed on a separate porous surface, the layers can be joined continuously in the wet state to form a multilayer tissue paper web.

As used herein, the term 'single-ply tissue product' means that the product consists of a single layer of uncreped tissue, where the ply of the tissue is substantially intact. It may be homogeneous or may be a multilayer tissue paper web. As used herein, the term 'multi-ply tissue product' means that the product consists of one or more uncreped tissues. Each ply of the multiply tissue product may be substantially homogeneous in nature or a multilayer tissue paper web.

The present invention in its most common form is a strong, soft tissue paper product consisting of one or more layers of tissue paper having a uniform discontinuous surface deposit of a chemical softener to which at least one outer surface of the product is substantially fixed.

As used herein, the term 'substantially affixed chemical softening agent' refers to lubricity in tissue paper products without substantial movement when exposed to environmental conditions that are normally exposed during typical usage cycles of tissue paper products. Or as a chemical agent that imparts emolliency and possesses the performance associated with maintaining the fidelity of the deposits of the product. For example, although waxes and oils can impart smoothness or softening to tissue papers, these materials tend to migrate because they have little affinity for the cellulose pulp comprising the tissue paper of the present invention. While not intending to be bound by theory, it is believed that the substantially fixed chemical emollients of the present invention interact with cellulose by sufficiently latent covalent, ionic or hydrogen bonding to inhibit migration in normal environmental conditions.

Preferred embodiments of the present invention are characterized as having uniform surface deposits spaced at a frequency between about 5 deposits per 2.54 cm to about 100 deposits per 2.54 cm long. Most preferably, the uniform surface deposits are spaced at a frequency between about 7 deposits per 2.54 cm to about 25 deposits per 2.54 cm in length.

The diameter of the uniform surface deposits of the chemical softener is preferably less than about 2700 microns, more preferably less than about 800 microns, and most preferably less than about 240 microns.

The invention is also characterized by having uniform surface deposits predominantly lying on one or more, preferably both, of the two outer surfaces of the tissue paper product.

Preferably, the substantially fixed chemical emollients include quaternary ammonium compounds. Preferred quaternary ammonium compounds have the formula

_{(R 1) 4-m -} N + - [R 2] m X -

Where

m is 1 to 3;

R ₁ is each C ₁ -C ₆ alkyl group, hydroxyalkyl group, hydrocarbyl or substituted hydrocarbyl group, alkoxylated group, benzyl group or mixtures thereof;

R ₂ is a C ₁₄ -C ₂₂ alkyl group, hydroxyalkyl group, hydrocarbyl or substituted hydrocarbyl group, alkoxylated group, benzyl group or a mixture thereof;

X ^_ is a particular softener-miscible anion suitable for use in the present invention.

Preferably, R ₁ is each methyl and X ^_ is chloride or methyl sulfate. Preferably, R ₂ is C ₁₆ -C ₁₈ alkyl or alkenyl, most preferably straight chain C ₁₈ alkyl or alkenyl, respectively. Optionally, R ₂ substituents can be derived from vegetable oil sources.

Compounds of this structure include the well-known dialkyldimethylammonium salts (e.g., ditallowdimethylammonium chloride) wherein R ₁ is a methyl group, R ₂ is a tallow group with variable saturation, and X ^_ is chloride or methyl sulfate. , Ditallowdimethylammonium methyl sulfate, di (hydrogenated tallow) dimethyl ammonium chloride, and the like.

Seen, Ed. As discussed in Bailey's Industrial Oil and Fat Products, Third Edition, John Wiley and Sons (New York 1964), tallow is a natural substance with a variable composition. Table 6.13 of the aforementioned Swen literature typically shows that at least 78% of the fatty acids of tallow contain 16 or 18 carbon atoms. Typically, half of the fatty acids present in the tallow are mainly unsaturated acids in the form of oleic acid. Natural 'tallows' as well as synthetic 'tallows' also fall within the scope of the present invention. It is also known that, depending on the properties of the product required, the saturation of the detalow can be adjusted by dehydrogenation (soft) or partially or fully hydrogenation (hard). All saturations mentioned above are clearly meant to be included within the scope of the present invention.

Particularly preferred among these softeners are believed to be mono or diester derivatives of the above-mentioned quaternary ammonium compounds having the formula (2):

(R ₁ ) _4-m -N ⁺ -[(CH ₂ ) _n -Y -R ₃ ] _m X ^_

Where

Y is -O- (O) C-, -C (O) -O-, -NH-C (O)-or -C (O) -NH-;

m is 1 to 3;

n is 0 to 4;

R ₁ is each C ₁ -C ₆ alkyl group, hydroxyalkyl group, hydrocarbyl or substituted hydrocarbyl group, alkoxylated group, benzyl group or mixtures thereof;

R ₃ is a C ₁₃ -C ₂₁ alkyl group, hydroxyalkyl group, hydrocarbyl or substituted hydrocarbyl group, alkoxylated group, benzyl group or a mixture thereof;

X ^_ is a certain softener-miscible anion.

Preferably, Y is -O- (O) C- or -C (O) -O-; m is 2; n is 2. Each R ₁ substituent is preferably a C ₁ -C ₃ alkyl group, with methyl being most preferred. R ₃ is each preferably C ₁₃ -C ₁₇ alkyl and / or alkenyl, more preferably straight C ₁₅ -C ₁₇ alkyl and / or alkenyl, most preferably straight C ₁₇ alkyl. Optionally, the R ₃ substituent may be derived from a vegetable oil source.

As mentioned above, X ^_ is a specific softener-miscible anion, for example acetate, chloride, bromide, methylsulfate, formate, sulfate, nitrate and the like may be used in the present invention. X ^_ is preferably chloride or methyl sulfate.

Specific examples of ester-functional quaternary ammonium compounds having the above-named structures and suitable for use in the present invention include diester dielow dimethyl ammonium chloride, monoester dielow dimethyl ammonium chloride, diester dielow dimethyl ammonium methyl sulfate Well-known diester dialkyl dimethyl ammonium salts such as diester di (hydrogenated) tallow dimethyl ammonium methyl sulfate, diester di (hydrogenated) tallow dimethyl ammonium chloride and mixtures thereof. Particular preference is given to diester dielow dimethyl ammonium chloride and diester di (hydrogenated) tallow dimethyl ammonium chloride. These specific materials are marketed under the trade name 'ADOGEN SDMC' by the Whitco Chemical Company, Dublin, Ohio.

As mentioned above, typically half of the fatty acids present in the tallow are unsaturated acids, mainly in the form of oleic acid. Natural 'tallows' as well as synthetic 'tallows' also fall within the scope of the present invention. It is also known that, depending on the properties of the product required, the saturation of the detalow can be adjusted by dehydrogenation (soft) or partially or fully hydrogenation (hard). All saturations mentioned above are clearly meant to be included within the scope of the present invention.

It will be appreciated that the substituents R ₁ , R ₂ and R ₃ may be optionally substituted with various groups, such as alkoxyl, hydroxyl, and the like. As mentioned above, each R ₁ is preferably methyl or hydroxyethyl. R ₂ is preferably each C ₁₂ -C ₁₈ alkyl and / or alkenyl, more preferably straight C ₁₆ -C ₁₈ alkyl and / or alkenyl, most preferably straight C ₁₈ alkyl or alkenyl. R ₃ is preferably C ₁₃ -C ₁₇ alkyl and / or alkenyl, most preferably straight C ₁₅ -C ₁₇ alkyl and / or alkenyl. X ^_ is preferably chloride or methyl sulfate. In addition, the ester-functional quaternary ammonium compounds are traces of up to about 10% of mono (long chain alkyl) derivatives, such as (R ₁ ) ₂ -N ⁺ -((CH ₂ ) ₂ OH) ((CH ₂ ) ₂ OC (O) R ₃ ) X ^_ may be optionally contained. Such trace ingredients can act as emulsifiers and are useful in the present invention.

Other types of quaternary ammonium compounds suitable for use in the present invention are described in US Pat. No. 5,543,067 to Phan et al. On August 6, 1996; US Patent No. 5,538,595 to Trocan et al. On July 23, 1996; U.S. Patent No. 5,510,000, issued to April et al. On April 23, 1996; U.S. Patent No. 5,415,737 to May 16, 1995; And in European Patent Application No. 0 688 901 A2, assigned to Kimberly-Clark Corporation and published December 12, 1995, all of which are incorporated herein by reference.

Di-quaternary variants of ester-functional quaternary ammonium compounds may also be used, meaning that they are included within the scope of the present invention. Such compounds have the formula

Wherein R ₁ is each a C ₁ -C ₆ alkyl or hydroxyalkyl group, R ₃ is a C ₁₁ -C ₂₁ hydrocarbyl group, X ^_ is a halide (e.g. chloride or bromide) or methyl sulfate Such is a suitable anion. Preferably R ₃ is preferably each C ₁₃ -C ₁₇ alkyl and / or alkenyl, most preferably C ₁₅ -C ₁₇ alkyl and / or alkenyl, and R ₁ is methyl.

Without wishing to be bound by theory, it is believed that the ester moiety (s) of the quaternary ammonium compounds mentioned above impart biodegradability to the compounds. Importantly, the ester-functional quaternary ammonium compounds used in the present invention biodegrade faster than conventional dialkyl dimethyl ammonium chemical emollients.

When the quaternary ammonium component described above is used together with a suitable plasticizer, the use of the quaternary ammonium component is most effective. Plasticizers may be added during the quaternization step in the preparation of the quaternary ammonium component or may be added prior to application as a chemical softener following the quaternization step. Plasticizers are characterized by being substantially inert during chemical synthesis, but act as a viscosity reducing agent which aids in synthesis and subsequent handling, i.e., application of quaternary ammonium compounds to tissue paper products. Preferred plasticizers consist of a mixture of non-volatile polyhydroxy compounds and fatty acids. Preferred polyhydroxy compounds are glycerol and polyethylene glycols having a molecular weight of about 200 to about 2000, with polyethylene glycol having a molecular weight of about 200 to about 600 being most preferred. Preferred fatty acids include C ₆ -C ₂₃ linear or branched, saturated or unsaturated analogs, of which isostearic acid is most preferred.

Without wishing to be bound by theory, Applicants believe that synergy is caused by the relationship of polyhydroxy compounds and fatty acids in the mixture. Polyhydroxy compounds exert an intrinsic function of reducing viscosity, but they can move considerably after attachment, thereby impairing one of the purposes of the present invention, namely, the purpose of substantially depositing deposited softeners. The inventors have now found that addition of a small amount of fatty acids can increase the processability of a composition containing a portion of quaternary ammonium compound by inhibiting the mobility of the polyhydroxy compound and also reducing the viscosity of the mixture. Came out.

Other embodiments of preferred substantially fixed chemical emollients include the well-known organo-reactive polydimethyl siloxane component, most preferably amino-functional polydimethyl siloxane.

The most preferred form of substantially fixed emollient is a mixture of organo-reactive silicone with a suitable quaternary ammonium compound. In this embodiment, the organo-reactive silicone is preferably amino polydimethyl siloxane, which is used in an amount ranging from 0 to about 50 weight of the composition. Preferred amounts of use range from about 5% by weight to about 15% by weight based on the weight of the polysiloxane with respect to the softened softener substantially.

The soft tissue paper of the present invention preferably has a dry weight of about 10 g / m 2 to about 50 g / m 2, more preferably about 10 g / m 2 to about 30 g / m 2. The soft tissue paper of the present invention has a density of about 0.03 g / cm 3 to about 0.6 g / cm 3, more preferably about 0.1 g / cm 3 to about 0.2 g / cm 3.

The soft tissue paper of the present invention further comprises papermaking fibers of both hardwood and softwood type, wherein at least about 50% of the papermaking fibers are hardwood and at least about 10% are softwood. Hardwood and softwood fibers are most preferably isolated by isolating them into separate layers, wherein the tissue paper comprises an inner layer and at least one outer layer.

The tissue paper product of the present invention is preferably creped, ie a Yankee dryer is attached to the last part of which a partially dried papermaking web is attached and removed therefrom by a flexible creping blade after the web is dried thereon. It manufactures on equipped paper machine.

Creping is a means of mechanically compacting paper in the machine direction. As a result, not only the dry weight (mass over unit area) increases, but also many properties change dramatically, especially when measured in the machine direction. Creping is generally performed using a flexible blade, the so-called doctor blade, for the Yankee dryer during machine operation.

Yankee dryers are drums with large diameters, typically from 2.44 to 6.10 m (8 to 20 ft), designed to pressurize with steam to provide a hot surface for completely drying the paper web at the end of the papermaking process. to be. Paper webs primarily formed on porous forming carriers, such as pod linear wires, that remove the abundant amount of water needed to disperse the fibrous slurry, are generally mechanically compressed or alternatively dewatered, such as aeration with hot air. Is transferred to the felt or fabric in a so-called pressurized section where dehydration is continued, and then finally transferred to the surface of the Yankee dryer in a semi-dried state and completely dried there.

In particular, when the creping process is carried out by the pattern densification method, although the characteristics of the creped paper web are preferred for carrying out the present invention, uncreped tissue is also a satisfactory substitute, specifically such creping It is also within the scope of the present invention to practice the invention using non-tissue paper. As used herein, the term Uncreped tissue paper refers to uncompressed tissue paper, most preferably fully dried tissue paper. The resulting fully dried web is pattern densified such that relatively dense bands are dispersed within a large volume area containing pattern densified tissue, where the relatively dense bands are continuous and large volume areas are discontinuous.

To produce an uncreped tissue paper web, the initial web is transferred from the porous molding carrier to a fabric carrier for high content fiber support delivery that moves more slowly. The web is then transferred to a drying fabric and dried thereon to final dryness. Such webs can provide some advantages in surface smoothness over creped webs.

Techniques for making uncreped tissues in this way are taught in the prior art. For example, European Patent Application No. 0 677 612 A2 to Went et al., Published October 18, 1995 and incorporated herein by reference, teaches a method for making soft tissue products without creping. In another case, European Patent Application 0 617 164 A1 to Highland et al., Published September 28, 1994 and incorporated herein by reference, teaches a method of making a smooth, uncreped, fully dried sheet. .

In general, tissue paper webs consist essentially of papermaking fibers. Usually includes small amounts of chemical functionalizing agents such as wet or dry strength binders, retention aids, surfactants, additives, chemical emollients, crepe promoting compositions, but typically they are only used in minor amounts. The papermaking fibers most commonly used in tissue paper are pure chemical wood pulp.

Filler materials may also be incorporated into the tissue paper of the present invention. United States Patent Application No. 08 / 418,990 to Vinson et al., Filed April 7, 1995 and incorporated herein by reference, discloses a filled tissue paper product that can be accepted as a description of the present invention.

Embodiments of the present invention wherein the substantially fixed softener comprises a quaternary ammonium compound include from about 1% to about 50% by weight of a polyhydroxy compound and from about 0.1% to about 10% by weight of the quaternary ammonium compound. It further comprises by weight fatty acid.

Polyhydroxy compounds useful in this embodiment of the invention include polyethylene glycol, polypropylene glycol and mixtures thereof.

Fatty acids useful in this embodiment of the invention include C ₆ -C ₂₃ linear or branched, saturated or unsaturated analogs. The most preferred form of fatty acid is isostearic acid.

One particularly preferred chemical emollient contains from about 0.1% to about 70% polysiloxane compound.

Polysiloxanes applicable to the chemical emollient composition of the present invention include polymeric, oligomeric, copolymerizable and other multicomponent monomeric siloxane materials. The term polysiloxane as used herein includes all such polymeric, oligomeric, copolymeric and other multicomponent monomeric siloxane materials. In addition, the polysiloxanes may be straight or branched chain or may have a cyclic structure.

Preferred polysiloxane materials are those having monomeric siloxane unit structures having the structure

Wherein R ₁ and R ₂ for the siloxane monomer units may each independently be a specific alkyl, aryl, alkenyl, alkaryl, aralkyl, cycloalkyl, halogenated hydrocarbon or other radical. These radicals may be substituted or unsubstituted. The R ₁ and R ₂ radicals of any particular monomeric unit may differ from the corresponding functional group of the monomeric unit to which they are next linked. In addition, these radicals may be straight or branched chain or may have a cyclic structure. The radicals R ₁ and R ₂ may additionally and independently be other silicone functional groups such as siloxanes, polysiloxanes and polysilanes, but are not limited to these. The radicals R ₁ and R ₂ may also contain certain various organic functional groups, including, for example, alcohol, carboxylic acid and amine functional groups.

Reactive organo-functional silicones, especially amino-functional silicones, are particularly preferred in the present invention.

Preferred polysiloxanes include straight chain organopolysiloxane materials of the formula:

Wherein R ₁ to R ₉ radicals may each independently be certain C ₁ -C ₁₀ unsubstituted alkyl or aryl radicals, and R ₁₀ may be certain substituted C ₁ -C ₁₀ alkyl or aryl radicals . Preferably, the R ₁ to R ₉ radicals are each independently a specific C ₁ -C ₄ unsubstituted alkyl group. Those skilled in the art will appreciate that there are no technical differences, for example whether R ₉ or R ₁₀ is a substituted radical. The molar ratio of b to (a + b) is preferably 0 to about 20%, more preferably 0 to about 10%, most preferably about 1 to about 5%.

In one particularly preferred embodiment, R ₁ to R ₉ are methyl groups and R ₁₀ is a substituted or unsubstituted alkyl, aryl or alkenyl group. Such materials will generally be described herein as polydimethylsiloxanes having certain functional groups that may be appropriate in certain cases. Exemplary polydimethylsiloxanes include, for example, polydimethylsiloxanes with alkyl hydrocarbon R ₁₀ radicals and one or more amino, carboxyl, ether, polyether, aldehydes, ketones, amides, esters, thiols and / or alkyls and als of these functional groups. Polydimethylsiloxanes with other functional groups, including kenyl analogs. For example, the amino functional alkyl group as R ₁₀ may be an amino-functional or aminoalkyl-functional polydimethylsiloxane. The exemplary polydimethylsiloxanes mentioned above are not meant to replace others not specifically mentioned.

The viscosity of the polysiloxanes useful in the present invention can generally vary as broadly as long as the viscosity of the polysiloxanes can vary, as long as such polysiloxanes can be in the form applicable to tissue products herein. Such viscosity ranges include, but are not limited to, ranges as low as about 25 centistokes to about 20,000,000 centistokes or more. High viscosity polysiloxanes which are resistant to flow on their own can be effectively deposited by emulsifying with a surfactant or by dissolving only in a vehicle such as hexane for illustrative purposes.

Without wishing to be bound by theory, it is believed that advantageous tactile effects are proportional to the average molecular weight and viscosity is also proportional to the average molecular weight. Thus, due to the difficulty in determining the molecular weight directly, the viscosity is used herein as an apparently functioning parameter associated with imparting softness to tissue paper.

References describing polysiloxanes include US Pat. No. 2,826,551 to Gene, dated March 11, 1958; U.S. Patent No. 3,964,500 to Drakoff, dated June 22, 1976; US Patent No. 4,364,837 to Pader, dated December 21, 1982; US Patent No. 5,059,282 to Ampulsky; US Patent No. 5,529,665 to Kaun, dated June 25, 1996; US Patent No. 5,552,020 to Smith et al. On Sep. 3, 1996; And British Patent 849,443 to Wooston, published September 28, 1960. All of these documents are incorporated herein by reference. Also, including examples of polysiloxanes and described generally in Silicone Compounds , pp. 181-217, distributed by Petrach Systems, Inc., is also incorporated herein by reference.

1 to 4 are provided for the purpose of illustrating the present invention.

1 is a side view of a printing apparatus illustrating a preferred method for forming a uniform surface deposit of a substantially fixed chemical softener of the present invention. The process illustrated in FIG. 1 is a process of applying a softener to one surface of a tissue paper product by an offset printing method.

In FIG. 1, the liquid chemical softener 6, which is preferably heated by means not shown, is contained in the fan 5, so that the rotary grabber cylinder 4 which is also heated by means not shown is It is partially immersed in the liquid chemical softener 6. The grabber cylinder 4 is substantially empty when they enter the fan 5 but is filled with a chemical softener 6 as the grabber cylinder 4 is partially immersed in the fluid in the fan 5 during cylinder rotation. It has a plurality of concave areas. The pattern of the graver cylinder 4 and its concave area will be exemplified later in FIG. 4, so a detailed description thereof will be held until a reference is made to the drawings.

Referring again to FIG. 1, excess chemical softener 6 collected from the fan 5 but not retained in the concave region contacts the grabber cylinder 4 on the outer surface but cannot be significantly deformed in the concave region. It is removed by the flexible doctor blade 7. Thus, the chemical softener remaining on the grabber cylinder 4 remains almost exclusively in the concave area of the grabber cylinder 4. This residual chemical softener is delivered to the applicator cylinder 3 in the form of a uniform discontinuous deposit. The applicator cylinder 3 can have any of a variety of surface cover layers provided suitable for the purposes of the present process. Most generally, the cylinder will have a metal cover layer. The load pressure increases as the grabber cylinder 4 and applicator cylinder 3 successfully penetrates the area 8 formed by the interference of the grabber cylinder 4 and the applicator cylinder 3. The grabber cylinder 4 and the applicator cylinder 3 will normally operate with interference since it will help the liquid chemical softener to be extracted from the concave region of c). In general, interference or substantial contact between the cylinder surfaces in the region 8 is preferred, but having only two cylinders passing in close proximity allows certain combinations of the size and shape of the concave region and chemical emollient fluid properties to be delivered satisfactorily. You can also think about it. The chemical softener extracted from the grabber cylinder 4 toward the applicator cylinder 3 in the region 8 is a surface deposit of the type corresponding to the size and separation distance for the pattern of the concave area of the grabber cylinder 4. Take form. The deposit of the chemical softener on the applicator cylinder 3 proceeds towards the region 9 defined by the point where the applicator cylinder 3, the tissue web 1 and the printing cylinder 2 are adjacent to each other. It is delivered to the tissue web 1. The printing cylinder 2 may have a variety of specific cover layers provided for the purpose of this process. Most typically, the cylinder will be covered with a compressible cover such as an elastomeric polymer such as natural or synthetic rubber. The printing cylinder 2 and the applicator cylinder 3 will normally operate without interference. Only when the tissue web is present in the area 9 is such tissue web contacting the convex deposits of chemical softener on the applicator cylinder 3 so that they are at least partially sufficient as the tissue web 1 in the applicator cylinder 3. Only cylinders that pass close enough to each other to be delivered are needed. Since the load pressure between the applicator cylinder 3 and the printing cylinder 2 will compress the tissue web 1, an extremely small gap between these two cylinders in order to preserve the thickness or volume of the tissue web 1. Should be eliminated. Although the interface or substantial contact between the cylinder surfaces (through which the tissue web 1 passes) in the region 9 is generally not essential, certain combinations of pattern and chemical softener properties are required for the two cylinders to work in contact with each other. You can also think about it. The tissue web 1 passes through the region 9 together with the side 11 containing a uniform surface deposit of substantially fixed softener according to the pattern of the graviator cylinder 4.

2 is a side view of a printing apparatus illustrating another method for forming a uniform surface deposit of a substantially fixed chemical softener of the present invention. The process illustrated in FIG. 2 is a process of applying a softener to one surface of a tissue paper product by a direct printing method.

In FIG. 2, the liquid softener 15 of the liquid phase, preferably heated by means not shown, is contained in the fan 14, and thus also preferably a rotary grabber cylinder (heated by means not shown). 13 is partially immersed in the liquid chemical softener 15. The grabber cylinder 13 is substantially empty when they enter the fan 14, but the chemical softener 15 is submerged while the grabber cylinder 13 is immersed in the fan 14 as it is partially immersed in the cylinder rotation. It has a plurality of concave areas filled with). The pattern of the graver cylinder 13 and its concave area will be exemplified later in FIG. 4, so a detailed description thereof will be withheld until a reference is made to the drawings.

Referring again to FIG. 2, excess chemical softener 15 collected from the fan 14 but not retained in the concave region contacts the grabber cylinder 13 on the outer surface but cannot be significantly deformed in the concave region. It is removed by the flexible doctor blade 16. Thus, the chemical emollient remaining on the grabber cylinder 13 remains almost exclusively in the concave region of the grabber cylinder 13. This remaining chemical emollient is transferred to the tissue paper web 1 towards the region 17 in the form of a uniform discontinuous deposit. This transfer is caused because the pressure of the printing cylinder 12 against the grabber cylinder 13 in the area 17 approaches the chemical softener present in the concave area. The printing cylinder 12 can have any of a variety of surface cover layers provided for the purpose of this process. Most typically, the cylinder will be covered with a compressible cover such as an elastomeric polymer such as natural or synthetic rubber. The load pressure is increased as the gravier cylinder 13 and the printing cylinder 12 successfully penetrate the area 17 formed by the interference of the gravier cylinder 13, the tissue web 1 and the printing cylinder 12. Since the chemical softener in the liquid phase will assist in the extraction of the liquid softener from the concave area of the gravier cylinder 13, the gravier cylinder 13 and the printing cylinder 12 are usually interfering, ie, in contact with the tissue paper web 1. Will work. In general, interference or substantial contact between the cylinder surfaces delivered through the tissue web 1 in the region 17 is preferred, but the size of the concave region by having only two cylinders passing in close proximity and a limited tissue web And the fact that certain combinations of shape and chemical softener fluid properties can be delivered satisfactorily. The tissue web 1 passes through the region 17 with the side 18 containing a uniform discontinuous surface deposit of a substantially fixed softener according to the pattern of the grabber cylinder 14.

3 is a side view of a printing apparatus illustrating another method for forming a uniform surface deposit of a substantially fixed chemical softener of the present invention. The process illustrated in FIG. 3 is a process of applying a softener to one surface of a tissue paper product by an offset printing method.

In FIG. 3, the liquid chemical softener 26, which is preferably heated by means not shown, is contained in the pan 27, so that the rotary grabber cylinder 25 also heated by means not shown. It is partially immersed in the liquid chemical softener 26. Gravure cylinders 25 are substantially empty when they enter into their respective fans 27 but chemically while they are immersed in fans 27 as the gravure cylinders 25 are partially immersed in them during rotation. It has a plurality of concave regions filled with softener 26. The pattern of the graver cylinder 25 and its concave area will be exemplified later in FIG. 4, so a detailed description thereof will be withheld until a reference is made to the drawings. The gravier cylinders 25 of FIG. 3 will typically be similar in design, but they may also be carefully modified, especially with regard to the pattern of concave areas. These differences can be used to apply product characteristics from side to side.

Referring again to FIG. 3, excess chemical softener 26 collected from the fan 27 but not retained in the concave region contacts the grabber cylinder 25 on the outer surface but cannot be significantly deformed in the concave region. It is removed by the flexible doctor blade 28. Thus, the chemical emollient remaining on the grabber cylinder 25 remains almost exclusively in the concave area of the grabber cylinder 25. This remaining chemical softener is delivered to the applicator cylinder 23 in the form of a uniform discontinuous deposit. The applicator cylinder 23 can have any of a variety of surface cover layers provided that are suitable for the purposes of the present process. Most generally, the cylinder may be covered with a compressible cover such as an elastomeric polymer such as natural or synthetic rubber. In general, the cylinders 23 will in fact be similar in character, but they are very different and can produce different properties of the product from side to side. Each pair of grabber cylinders 25 with individual applicator cylinders 23 successfully penetrates their respective interference regions 24 formed by the interference of the grabber cylinder 25 and the applicator cylinder 23. Grabber cylinder 25 and applicator cylinder 23 will typically operate with interference since the load pressure between the pair of cylinders will help the liquid chemical softener to be extracted from the concave region of the grabber cylinder 25. will be. In general, interference or substantial contact between the cylinder surfaces in one or both regions 24 is preferred, but having only one or more cylinder pairs that pass through in close proximity may specify the size and shape of the concave region and the chemical softener fluid properties. It is also conceivable that the combination can be delivered satisfactorily. The chemical softener extracted from the grabber cylinder 25 toward the applicator cylinder 23 in the area 24 is in the form of surface deposits corresponding to the size and separation distance for the pattern of the concave area of the grabber cylinder 25. Take it. Deposits of chemical softener on the applicator cylinder 23 are transferred to the tissue web 1 running toward the area 22 as the chemical softener penetrates the area 22. The area 22 is formed by the applicator cylinder 23 at the point closest to the tissue web 1 passing between the applicator cylinders 23. The applicator cylinder 23 will typically operate without interference, ie without contacting each other. When the tissue web is present in the area 22 such tissue web is in contact with deposits of chemical softener on each applicator cylinder 23 such that the deposit is at least partially at the tissue web 1 in the applicator cylinder 23. The cylinders pass close enough to each other so that they are sufficiently delivered. Since the load pressure between the applicator cylinders 23 will compress the tissue web 1, it is necessary to close the extremely small gap between these two cylinders in order to preserve the thickness or volume of the tissue web 1. Interference or substantial contact between the cylinder surfaces (through the tissue web 1) in the area 22 is generally not essential, but as the two cylinders operate in contact with each other as they are transmitted through the tissue web 1. It may be contemplated that certain combinations of pattern and chemical softener properties may be required. The tissue web 1 passes through the area 22 with both sides 29 containing uniform discontinuous surface deposits of substantially fixed softener according to the pattern of the grabber cylinder 25.

FIG. 4 is used on the printing cylinders illustrated in FIGS. 1, 2 and 3, ie the gravier cylinder 4 of FIG. 1, the gravier cylinder 13 of FIG. 2, and the gravier cylinder 25 of FIG. 3. It is a schematic diagram detailing the concave area | region which becomes.

Referring to FIG. 4, the grabber cylinder 31 possesses a plurality of concave regions, sometimes referred to as cells. This concave region 33 is present on another smooth cylindrical surface 32.

The cylinder 31 may be made of various materials. In general, this will be relatively incompressible, such as metal rolls or ceramic rolls, but elastomeric roll covers are also possible.

Most preferably, the surface of the cylinder 31 is a ceramic such as aluminum oxide. Such materials can produce multiple concave regions by engraving such materials with a laser beam that is well known in the printing process industry to the surface.

Another means of creating recessed areas on the cylinder 31 is to electromechanically type them using an electronically controlled vibratory technique of diamond tipped cutting tools. If this method is chosen, it is most convenient to wrap the surface of the roll with copper until it is typeset and plated with a thin chrome furnish to protect the soft copper layer.

Another means of creating a concave region on the cylinder 31 is to chemically etch the concave regions into a concave region 33 using an unstable roll surface protected by a chemically resistant mask fixed on the roll surface. It is a method of suppressing etching of regions which should not be. If this method is chosen, it is also most convenient to wrap the surface of the roll with copper until the roll is etched and then plated with a thin chrome furnish to protect the soft copper layer.

Finally, another means of creating a concave region on the cylinder 31 is a method of mechanically engraving the regions using a convex cutting tool. In this way it is possible to manufacture cylinders using the widest variety of materials, but it is almost impossible to modify the achievable pattern.

The separation distance 34 of the concave cell 33 on the cylinder surface 32 ranges from 5 to 100 concave regions per 2.54 cm. The geometry of each concave region is hemispherical.

4A illustrates in more detail a concave region preferred for use in the present invention by illustrating one of the concave regions in a cross sectional view. In FIG. 4A, the grabber cylinder 42 includes a hemispherical concave region having a diameter in the range of 130 microns to 410 microns.

Wood pulp in all of its variants is generally thought to include tissue paper useful in the present invention. However, other cellulose fibrous pulp such as cotton linter, bagasse, rayon and the like may be used, and nothing is rejected. Wood pulp useful in the present invention is, for example, ground pulp, as well as mechanical pulp, including pulverized wood, ThermoMechanical Pulp (TMP) and ChemiThermoMechanical Pulp (CTMP). Chemical pulp such as fighter and sulfate pulp (so-called kraft pulp). Pulps derived from both hardwoods and conifers can be used.

Hard wood pulp and soft wood pulp as well as mixtures of these two pulp can be used as papermaking fibers for making the tissue paper of the present invention. As used herein, the term 'hardwood pulps' refers to fibrous pulp derived from woody fiber material of hardwoods (pizza plants), while the term 'softwood pulps' refers to softwood (Naja). Fibrous pulp derived from the woody fibrous material of plants). Particularly suitable for producing the tissue webs of the present invention are blends of hardwood kraft pulp, in particular eucalyptus and northern softwood kraft (NSK) pulp. A preferred embodiment of the present invention most preferably comprises the use of a multi-layer tissue web wherein hardwood pulp, such as eucalyptus, is used in the outer layer (s) and northern softwood kraft pulp is used in the inner layer (s). do. Fibers derived from recycled paper, which may contain some or all of the aforementioned fibers, may also be used in the present invention.

In one preferred embodiment of the invention using a plurality of papermaking furnishes, the furnish containing the papermaking fibers to be in contact with the particulate filler is preferably a hardwood of the type which preferably has a hardwood content of preferably at least about 80%. Is done.

Any chemical additives

As long as they are chemically compatible with substantially fixed chemical emollients and do not significantly affect the flexibility, strength or low dust properties of the present invention, other materials may be used for aqueous papermaking to impart other properties to the product or to improve the papermaking process. It can be added to the furnish or the initial web. The substances mentioned below may be included but are not limited to these. Other materials may be included so long as they do not interfere with the benefit of the present invention.

Typically, cationic charge bias species are added to the papermaking process to control the zeta potential of the aqueous papermaking furnish as it is transferred to the papermaking process. The reason these materials are used is that in fact most solids have a negative surface charge, such as the surface of cellulose fibers and particulates and most inorganic fillers. One commonly used cationic charge bias species is alum. Recently, in the art, a relatively low molecular weight cationic synthetic polymer having a relatively low molecular weight, preferably about 500,000 or less, more preferably about 200,000 or less, most preferably about 100,000 or less, is used to bias the charge. . The charge density of such low molecular weight cationic synthetic polymers is relatively high. Such charge densities range from about 4 to about 8 equivalents of 1 kg of cationic nitrogen / polymer. One example of such a material is Cypro 514 ^R , manufactured by Cytec, Inc. of Stamford, Connecticut. Such materials are clearly used to practice the invention.

It is taught in the art to use high surface area, high negative charge particulates to improve molding, drainage, strength and retention. This is taught, for example, in US Pat. No. 5,221,435, issued June 22, 1993, to Smith, which is incorporated herein by reference. Typical materials used for this purpose are silica colloids or bentonite clays. Incorporation of such materials is clearly within the scope of the present invention.

Polyamide-epichlorohydrin, polyacrylamide, styrene-butadiene latex, where permanent wet strength is required; Insoluble polyvinyl alcohol; Urea-formaldehyde; Polyethyleneimine; Compounds selected from the group consisting of chitosan polymers and mixtures thereof can be added to the papermaking furnish or initial web. Polyamide-epichlorohydrin resins are cationic wet strength resins that have been found to have particular utility. Suitable resins of this type are U. S. Patent Nos. 3,700, 623 issued October 24, 1972 and U. S. Patent No. 3,772, 076 issued November 13, 1973, respectively, to Keim and incorporated herein by reference. It is described in One manufacturer of useful polyamide-epichlorohydrin resins is Hercules, Inc., Wilmington, Delaware, USA, which uses such resins as Kymene 557H. ^It is marketed under the trade name ^R.

Many paper products must have a limited strength, because these paper products need to be disposed of in a decay or sewage system through the toilet. If the wet strength is imparted to these products, it is desirable to eliminate the wet strength, characterized by the fact that some or all of them collapse immediately when the product is left in the presence of water. In order to eliminate the wet strength, the binder may be dialdehyde starch or Co-Bond 1000 ^R sold by National Starch and Chemical Company, Stamford, Connecticut. Parez 750 ^R , available from Cytec, Inc., and the resins described in US Pat. No. 4,981,557, incorporated herein by reference and issued to Bjorkquist on January 1, 1991. It can be selected from the group consisting of other resins with aldehyde functional groups such as.

If improved absorbency is needed, surfactants can be used to treat the tissue paper web of the present invention. If used, the level of surfactant is preferably from about 0.01% to about 0.2% by weight based on the dry fiber weight of the tissue paper. Such surfactants preferably have alkyl chains having 8 or more carbon atoms. Examples of anionic surfactants are linear alkyl sulfonates and alkylbenzene sulfonates. Examples of non-ionic surfactant (based upon US, New York, NY) The chroman,, Inc., such as alkyl (Croda, Inc.) chroman having star ^{SL-40 R (Crodesta SL-} 40 R) that is commercially available from Glycoside esters; Alkylglycoside ethers as described in US Pat. No. 4,011,389 to WK Langdon, dated Mar. 8, 1977; And 200 ML Pegosperse, available from Glyco Chemicals, Inc., Greenwich, Connecticut, and Ron Forlenk Corporation, Cranbury, NJ. Alkylglycosides including alkylpolyethoxylated esters such as Igepal RC-520 ^R (IGEPAL RC-520 ^R ) available from Rhone Poulenc Corporation.

While in the nature of the present invention there is a substantially fixed chemical emollient composition deposited in the form of uniform and discontinuous deposits on the surface of the tissue paper web, the present invention also provides a modification of adding a chemical emollient as part of the papermaking process. Include clearly. Acceptable chemical emollients include well-known dialkyldimethylammonium salts such as ditallowdimethylammonium chloride, ditallowdimethylammonium methyl sulfate, di (hydrogenated) tallow dimethyl ammonium chloride, and double di (hydrogenated) tallow Dimethyl ammonium methyl sulfate is preferred. These particular materials are available to wit co Chemical Company, Inc. (Witco Chemical Company Inc.) Bari soft 137 ^R (Varisoft 137 ^R), located in the City of Dublin, Ohio, USA, is the product name. Biodegradable mono- and di-ester variants of quaternary ammonium compounds may also be used, which is within the scope of the present invention.

Any of the chemical additives listed above are for illustration only and they do not limit the scope of the invention.

The tissue paper web according to the present invention has a basis weight of 10 g / m 2 to about 100 g / m 2. In a preferred embodiment, the filled uncreped tissue paper produced by the present invention has a basis weight of about 10 g / m 2 to about 50 g / m 2, most preferably about 10 g / m 2 to about 30 g / m 2. The uncreped tissue paper web produced by the present invention has a density of about 0.60 g / cm 3 or less. In a preferred embodiment, the filled uncreped tissue paper of the present invention has a density between about 0.03 g / cm 3 and about 0.6 g / cm 3, most preferably between about 0.05 g / cm 3 and about 0.2 g / cm 3.

The invention is also applicable to the production of multilayer tissue paper webs. Multilayer tissue structures and methods of forming such multilayer tissue structures are described in US Pat. No. 3,994,771 to Morgan, Jr., et al. On Nov. 30, 1976, and US Pat. No. 4,300,981 to Karstentm on Nov. 17, 1981. And U.S. Patent No. 4,166,001 to Dunning et al. On August 28, 1979 and European Patent Publication No. 0 613 979 A1, published on September 7, 1994, et al. All of these documents are incorporated herein by reference. The layers are preferably composed of different fiber types, such fibers being representative of relatively long softwood and relatively short hardwood as used in multilayer tissue paper. The multi-layered tissue paper obtained by the present invention consists of at least two overlapping layers and at least one outer layer continuous with the inner layer and the inner layer. Preferably, the multi-layer tissue paper consists of three overlapping layers, an inner or central layer and two outer layers, wherein the inner layer is located between the two outer layers. These two outer layers preferably consist of the main filament component of the relatively short papermaking fibers having an average fiber length of less than about 0.5 to about 1.5 mm, preferably less than about 1.0 mm. Such short papermaking fibers typically comprise hardwood fibers, preferably hard kraft fibers, most preferably fibers derived from eucalyptus. The inner layer preferably consists of the main filament component of the relatively long papermaking fiber having an average fiber length of at least about 2.0 mm. Such long papermaking fibers are typically soft fibers, preferably northern soft kraft fibers. The particulate filler of the present invention is preferably primarily included in one or more outer layers of the multilayer tissue web of the present invention. More preferably, the particulate filler of the present invention is included in both outer layers.

Tissue paper products made from single- or multi-layer tissue paper webs may be single-ply tissue products or multi-ply tissue products.

In the practice of the present invention, a low concentration pulp furnish is provided in a pressurized headbox. The headbox has an opening for delivering a thin deposit of pulp furnish to the podlinear wire to form a wet web. This web is then dewatered, typically by vacuum dehydration, at a fiber concentration of about 7% to about 25% based on the total web weight.

To produce a filled tissue paper product having utility in the present invention, an aqueous papermaking furnish is deposited on a porous surface to form an initial web. Methods of making tissue products by forming multiple paper layers are also within the scope of the present invention, wherein the two or more finish layers are separate streams of separate streams of thin fiber slurry, for example in a multi-channel headbox. Preference is given to depositing and forming. These layers are preferably composed of different types of fibers, which are representative of relatively long softwood and relatively short hardwood fibers as used in the production of multilayer tissue paper. When forming individual layers on separate wires, these layers are combined when wet to form a multilayer tissue paper web. Papermaking fibers are preferably composed of different types of fibers, and these fibers are representative of relatively long softwood and relatively short hardwood fibers. More preferably, hardwood fibers comprise at least about 50% of the papermaking fibers and softwood fibers comprise at least about 10% of the papermaking fibers.

As used herein, the term 'strength' refers to a particular total tensile field, and the method of determining that measurement is described in the following paragraphs. The tissue paper web according to the present invention is rigid. This generally means that the specific total tensile strength is at least about 200 m, more preferably at least about 300 m.

'Lint' and 'dust' are used interchangeably herein and refer to the relaxation of the tissue paper web into fibers or particulate filler as measured by a controlled abrasion test method, as described in detail later. . Lint and dust are related to strength because the tendency of the fibers or particles to relax is directly related to the extent to which the fibers or particles are fixed to the structure. As overall fixation increases, so will strength. However, it is possible to have a level of strength that is considered to have an acceptable but unacceptable level of lint and dust. This is because lining or dusting can be local. For example, while the surface of the tissue web can be proved by lining or dusting, the degree of bonding below the surface is sufficient to raise the overall level of strength to an almost acceptable level. In other cases, the strength is derived from the skeleton of relatively long papermaking fibers, while fibrous particulates or particulate fillers may be insufficiently bound in the structure. The tissue paper web of the present invention has a relatively low lint. Lint levels of about 12 or less are preferred, about 10 or less are more preferred, and 8 or less are most preferred.

The multilayer tissue paper web of the present invention can be used where a soft, absorbent multilayer tissue paper web is desired. A particularly advantageous use of the multilayer tissue paper web of the present invention is in toilet tissues and cosmetic tissue products. Single and multi-ply tissue paper products are made from the web of the present invention.

Analysis and test procedure.

A. Density

As used herein, the density of a multi-layer tissue paper is the average density calculated by dividing the basis weight of the paper by the caliper, according to the appropriate unit conversion embedded therein. The caliper of the multi-layer tissue paper used herein is the thickness of the paper when subjected to a compressive load of 95 g / in ² (15.5 g / cm ² ).

B. Measurement of Tissue Paper Lint

The amount of lint generated from the tissue product is measured using a Sutherland Rub tester. This tester uses a motor to rub the weighted felt five times on a fixed toilet tissue. Hunter color L value is measured before and after the friction test. The difference between these two Hunter color L values is calculated as lint.

Sample manufacturing process

Before the lint friction test, the paper samples to be tested should be in accordance with Tappi Method # T4020M-88. Here, the samples are preconditioned for 24 hours at a relatively humid level of 10 to 35% and at 22 to 40 ° C. This friction test is performed indoors at constant temperature and humidity.

Sutherland Friction Tester uses a product of Testing Masyns Inc., Amityville, NY. The tissue is first produced by removing the product which is manually ground on the outside of the roll. For the multiply intermediate part, three sections, each containing two sheets of multiply product, are removed and set up on the bench top. For a single ply product, six cross sections each containing two sheets of single ply product are removed and set up on the bench-top. Each sample is folded in half to run along the transverse direction (CD) of the tissue sample. For a multi-ply product, after the sample is folded, one of the sides facing each other is in the same side facing each other. That is, the strands that are separated from each other do not tear each other, and the side facing each other is subjected to a friction test on the inside of the product. For single ply products three samples are on the wire side and three samples are on the non-wire side.

Obtain 30 'x 40' pieces of Crescent # 300 from Cordage Inc., 45217 East Ross Road, Ohio. Using a paper cutter, cut six pieces of cardboard measuring 6.35 cm by 15.24 cm (2.5 'by 6'). Two holes are drilled for each of the six cards by pressing the cardboard onto the holddown pin of the Sutherland friction tester.

Working with a single-ply product, carefully center each of the 6.35 cm by 15.24 cm dimensions cardboard on top of the sample already folded six times. A cardboard measuring 15.24 cm is allowed to run parallel to the machine direction (MD) of each tissue sample. When working with multiple layers, only three 6.35cm × 15.24cm cardboards are required. Carefully center each of the pieces of cardboard on top of the sample that has already been folded three times. Again, a 15.24 cm cardboard is run parallel to the machine direction (MD) of each tissue sample.

Fold one edge of the exposed portion of the tissue sample on the back of the cardboard. These edges are glued to the cardboard with 3M Inc.'s 3.62 / 10.16 cm (3/4 ') wide Scotch brand adhesive tape from St. Paul, Minn. Grip the edge of the protruding tissue of the guitar and fold it invisibly on the back of the cardboard. While holding the invisible joint of the paper on the board, the second edge is taped to the backside of the cardboard. Repeat this procedure for each sample.

Turn each sample over and tape the transverse edges of the tissue to the cardboard. Half of the adhesive tape must be in contact with the tissue, while the other half is glued to the cardboard. Repeat this procedure for each sample. If the tissue sample breaks and tears or becomes tattered during this sample preparation procedure, a new tissue sample is made from the tissue sample strip after discarding.

Working with a multi-switched product, there are three samples on the cardboard. For a single ply product, there are three wire sideout samples on the cardboard and three nonwire sideout samples on the cardboard.

Felt manufacturing

Obtain a 76.2 cm x 101.6 cm (30 '× 40') piece of Gradient # 300 from Cordage Inc., 45217 Cincinnati East Ross Road, Ohio. Using a paper cutter, cut six pieces of cardboard measuring 2.72 'by 7.25' (5.72 cm by 18.42 cm). Draw two parallel lines a little below 2.86 cm (1.125 ') from the top and bottom edges on the white side of the cardboard. Carefully fill in the length of the line with a razor blade using a straight edge as a guide. Fill in approximately half the depth through the thickness of the sheet. This entry fits tightly to the cardboard / felt combination to withstand the weight of the Sutherland Friction Tester. On this written side of the cardboard draw an arrow running parallel to the long dimension of the cardboard.

Black felt [F-55 from New England Gasket, Bristol Board Street 550, Connecticut, 550 or its equivalent] is 5.72 cm x 21.59 cm x 0.159 cm (2.25 'x 8.5' x 0.0625 ') Cut into 6 pieces with the dimensions of. The black felt is placed on top of the unwritten green side of the cardboard so that the long edges of the felt and the cardboard are parallel and aligned. Make sure the felt side of the felt faces each other. It should also protrude approximately 1.27 cm (0.5 ') above and below the edge of the cardboard. Fold it squarely with Scotch tape, overlapping the protruding felt edges on the back of the cardboard. A total of six such felt / cardboard combinations are prepared.

For good reproducibility, all samples run with felt of the same lot. Clearly, there is a case where the felt of a single lot is completely consumed. In such a case, a new lot must be felt. The correction factor should be determined for the felt of the new lot. To determine the correction factor, a representative single tissue sample and enough felt are made to make 24 cardboard / felt samples for the old and new lots.

Hunter L plates for each of the 24 cardboard / felt samples of the felt of the old and new lot are obtained before friction occurs as described below and above. Calculate the averages for the 24 cardboard / felt samples of the new lot and the 24 cardboard / felt samples of the old lot.

Subsequently, a friction test is carried out on the 24 cardboard / felt board of the spherical lot as described below and the 24 cardboard / felt board of the new lot. The same tissue lot number is used for each of 24 samples for new and old lots. In addition, the sampling of the paper in the manufacture of the cardboard / tissue sample should be done with the felt of a new lot, and the felt of the spherical lot is exposed as possible as a representative tissue sample. For single-ply tissue products, discard damaged or worn products. Then, 48 strips of tissue are obtained, each of which is both available units (otherwise sheets). Place the two available monomer strips on the far left of the lap bench and the last 48 strip samples on the far right of the bench. Samples are marked on the left most by the number '1' in the 1 cm x 1 cm area of the sample corner. Samples are displayed consecutively up to 48 so that the rightmost final sample is digitized to 48.

Use 24 odd samples for new felt and 24 even samples for spherical felt. Odd samples are placed in order from lowest to highest and even samples are placed in order from lowest to highest. The lowest number for each is denoted by the letter 'W'. The highest number below is represented by the letter 'N'. Samples are displayed continuously with this optional 'W' / 'N' pattern. The 'W' sample is used for wire sideout lint analysis and the 'N' sample is used for non-wire side lint analysis. For single ply products, there are a total of 24 samples for felt of old and new lots. Of these 24, 12 are for wire sideout lint analysis and 12 are for nonwire side lint analysis.

By rubbing as described below, the Hunter collar L value is measured for all 24 samples of the spherical felt. Record the 12-wire side hunter collar L value for the spherical felt. Average 12 values. Record the 12 nonwire side hunter collar L values for the spherical felt. Average 12 values. Subtract the average initial non-frictional Hunter collar L felt plate from the average Hunter collar L plate for wire side rubbed samples. This is the delta mean difference for the wire side sample. Subtract the average initial non-frictional Hunter collar L felt plate from the average Hunter collar L plate for nonwire side rubbed samples. This is the delta mean difference for nonwire side samples. Calculate the sum of the delta mean difference for the wire side and the delta mean difference for the non-wire side and divide the sum by 12. This is the uncorrected lint value of the spherical felt. If there is a recent felt correction factor for the spherical felt, add it to the uncorrected lint value for the spherical felt. This value is a correction lint value for spherical felt.

Rub as described below to determine the Hunter color L value for all 24 samples of fresh felt. Record the 12-wire side hunter collar L for the new felt. Average 12 values. Record the 12 nonwire side hunter collar L values for the new felt. Average 12 values. Subtract the average initial non-frictional Hunter collar L felt plate from the average Hunter collar L plate for wire side rubbed samples. This is the delta mean difference for the wire side sample. Subtract the average initial non-frictional Hunter collar L felt plate from the average Hunter collar L plate for nonwire side rubbed samples. This is the delta mean difference for nonwire side samples. Calculate the sum of the delta mean difference for the wire side and the delta mean difference for the non-wire side and divide the sum by two. This is the uncorrected lint value of the new felt.

The difference between the corrected lint value from the old felt and the uncorrected lint value for the new felt is taken. This difference is the felt correction factor for the felting of the new lot.

Adding this felt correction factor to the uncorrected lint value for the new felt should be the same as the corrected lint value for the spherical felt.

The same procedure applies to a two-ply tissue product having 24 sample runs for old felt and 24 sample runs for new felt. However, only the outer layer of strands used by the user is tested by rubbing. As described above, samples are prepared to obtain representative samples for old and new felt.

Role of 1.5 kg (4 lbs)

1.5kg weight has an effective contact area of 25.81cm ² (4in ²⁾ providing a contact pressure of (1 pound per 1in ²⁾ 703kg per 1m ^2. Since the contact pressure can be changed by the change of the rubber pad installed on the surface of the weight body, only the rubber pad provided by the manufacturer (Brown Inc., Calama, Mich.) It is important to use. These pads should be replaced when they become hard, worn or broken.

When not in use, this weight must be positioned so that the pad does not support the total weight of the weight. It is best to store the weight upright on its side.

RUB TESTER INSTRUMENT CALIBRATION

Sutherland Friction Tester shall be calibrated before use. First, turn on the Sutherland Friction Tester by moving the switch on the Sutherland Friction Tester to the 'cont' position. When the tester arm is in the closest position to the user, turn the switch of the tester to the 'auto' position. Set the tester to move the tester five times by moving the pointer arm of the large dial to the 'five' position setting. One time means one complete forward and backward movement of the weight. The end of the friction block shall be in the position closest to the operator at the beginning and end of each test.

As described above, tissue paper is prepared on a cardboard sample. In addition, a felt is prepared on the cardboard sample as described above. These two samples will be used for the calibration of the tool and will not be used to obtain data on the actual samples.

Slide the hole in the board over the hold down pin to place this assay tissue sample on the base plate of the tester. The hold down pin prevents the sample from moving while being tested. The black felt / cardboard sample is placed on a 4 pound weight so that the cardboard side contacts the pad of the weight. The cardboard / felt combination is left flat by the weight. This weight is hung on the tester arm and the tissue sample is gently placed under the weight / felt combination. The weight end closest to the operator should be above the cardboard of the tissue sample, not the tissue sample itself. The felt should be flat on the tissue sample and in 100% contact with the tissue surface. 'Press the push button to run the tester.

Observe counts and identify the starting and stopping positions of the felt-covered weights relative to the sample. If the total number of times is five and the end of the felt covered body at the beginning and end of the test is closest to the operator on the cardboard of the tissue sample, the tester is tested and ready for use. If the total number is not five or if at the beginning or end of this test the end of the felt-weighted body closest to the operator is actually on the paper tissue sample, the number is five. The assay procedure is repeated until the end of the felt covered body closest to the operator is on the cardboard at both the beginning and end of this test.

During the actual test of the sample, count the number of times and observe the start and end points of the felt-covered weights. Retest if necessary.

Hunter color meter black

Adjust the Hunter Color Difference Meter for the black and white standard plates following the procedure described in the instrument's operating instructions. In addition, if not run in the last 8 hours, a daily color stability check and stability check for standardization are run. In addition, the reflectance should be checked to zero and readjusted if necessary.

Place the reference whiteboard above the sample stage below the tool port. Remove the sample stage and place the sample plate directly under the sample port.

When the 'L', 'a' and 'b' pushbuttons are pressed in sequence, the 'L', 'a' and 'b' Adjust the tool to read the reference whiteboard value.

Sample measurement

The first step in the determination of lint is to measure the hunter color value of the black felt / cardboard sample before rubbing on the tissue. The first step in this measurement is to lower the reference whiteboard tool from under the port of the Hunter collar tool. Position the felt covered cardboard in the center, with the arrow at the top of the reference plate pointing to the back of the color meter. Remove the sample stage and raise the felt covered cardboard below the sample port.

Since the width of the felt is only slightly larger than the diameter of the visible area, be sure to completely cover the felt area. After confirming that the cover is completely covered, press the L pushbutton and wait for the scale to stabilize. Read and record this L value to the nearest 0.1 unit.

If the D25D2A head is in use, lower the felt covered cardboard and plate and rotate the felt covered cardboard about 90 degrees so that the arrow points to the right of the meter. After that, remove the sample stage and check once more that the visible area completely covers the felt. Press the L pushbutton. Read and record this L value to the nearest 0.1 unit. For the D25D2M device, the value recorded is the Hunter color L value. For the D25D2A head where the rotated sample scale is also recorded, the Hunter color L value is the average of the two recorded values.

This technique is used to measure the Hunter color L for all felt covered cardboard. If the Hunter color L values are all within 0.3 units, the average is taken to get the initial L scale. If the Hunter color L value is not within 0.3 units, discard the felt / cardboard combination outside the limit. Prepare a new sample and repeat Hunter color L measurements until all samples are within 0.3 units.

For the measurement of the actual tissue paper / cardboard combination, slide the holes of the board over the hold down pins and place the tissue sample / cardboard combination on the base plate of the tester. The hold down pin prevents the sample from moving during the test. The black felt / cardboard sample is placed on a 4 pound weight so that the cardboard side contacts the pad of the weight. The cardboard / felt combination is left flat by the weight. This weight is hung on the tester arm and the tissue sample is gently placed under the weight / felt combination. The weight end closest to the operator should be above the cardboard of the tissue sample, not the tissue sample itself. The felt should be flat on the tissue sample and in 100% contact with the tissue surface. Then, press the 'push' button to operate the tester. The final five testers will automatically shut down. Note the stop position of the felt-covered weight in relation to the sample. If the end facing the operator of the felt-covered weight is on the cardboard, the tester is performing properly. If the end facing the operator of the felt-covered weight is on the cardboard, discard the measurement and retest as mentioned in the Sutherland Friction Tester assay.

Remove the weight with a felt covered cardboard. Examine the tissue sample. If it is torn, discard the felt and tissue and start over. If the tissue sample is at rest, remove the felt covered cardboard from the weight. As described above for the blank felt, the Hunter color L value is determined for the felt covered cardboard. After rubbing, record the Hunter collar L scale for the felt. Hunter color L values are recorded by rubbing and measuring for all remaining samples.

After all tissues have been measured, remove all felt and discard. The felt strip is not used again. The cardboard is used until it is bent, torn, softened and no longer has a smooth surface.

Calculation

Delta L values are determined by subtracting the average initial L scale value found by measuring for unused felt from each of the measurements on the wire side and nonwire side of the sample. Remember that a multiply product only rubs one side of the paper. Thus, three delta L values will be obtained for multiplexing. The three delta L values are averaged and the felt factor is subtracted from this final average value. This final result is defined as lint for two-ply products.

For single-ply products where wire side and non-wire side measurements are obtained, subtract the average initial L scale found for the unused felt from each of the three wire side L scale values and each of the three non-wire side L scale values. . The average delta is calculated for the three wire side values. Calculate the average delta for three non-wire surveys. The felt factor is subtracted from each of the three mean values. The final result is defined as lint on the non-wire side and lint on the wire side of the single-ply product. By taking the average of these two values, the final lint for the whole single-ply product is obtained.

C. Measuring Panel Flexibility in Tissue Paper

Ideally, before making flexibility measurements, the paper samples to be tested should be conditioned according to Top Peer Method # 402OM-88. Here, samples are preconditioned for 24 hours at a relative humidity level of 10 to 35% at 22-40 ° C. After this preconditioning step, the sample should be adjusted for 24 hours at a relative humidity level of 48-52% at 22-24 ° C.

Ideally, the flexible panel test is conducted in a thermo-hygrostat area. If this is not possible, all samples, including the regulator, should be done under the same exposure environmental conditions.

Flexibility testing is a reference to the Manual on Sensory Testing Methods of ASTM Special Technical Publication No. 434, which is incorporated herein by reference and published by the American Society For Testing and Materials in 1968. Is performed as a comparison in pairs in a form similar to that described in. Flexibility is assessed by subjective testing using what is referred to as the paired difference test. This method uses the reference appearance for the test material itself. For the tactile perception flexibility, two samples are provided so that the subject cannot see the sample, and the subject is required to select one of them based on the tactile perception method. The results of the test are reported in a form called Panel Score Unit (PSU). In connection with the flexibility test to obtain the flexibility data reported here in the form of PSUs, a number of flexibility panel tests are performed. In each test, ten flexibility judgments made are required to evaluate the relative flexibility of three sets of paired samples. Sample pairs are evaluated one pair at a time in each judgment: one sample of each pair is designated X and the rest are designated Y. In short, each X sample is rated for its partner Y sample as follows:

1. If X is judged to be slightly softer than Y, it is given a rating of +1; if it is determined that Y may be slightly softer than X, it is given a rating of -1;

2. If X is clearly slightly softer than Y, then a rating of +2 is given; if Y is clearly slightly softer than X, then a rating of -2 is given;

3. If X is judged to be considerably softer than Y, then a rating of +3 is given, and if Y is obviously considerably softer than X, then a rating of -3 is given;

4. If X is judged to be slightly softer than Y, then a rating of +4 is given, and if Y is considerably softer than X, a rating of -4 is given.

The grades are averaged and the resulting values are expressed in units of PSU. The resulting data is considered as the result of one panel test. Once more than one sample pair is evaluated, all sample pairs are ordered according to their rank by statistical analysis using the pair. The rating is then adjusted up or down depending on the value, i.e., the value that is required to give a zero PSU value so that the sample is selected to be a zero base reference for the zero PSU value. The other samples then have a + value or a-value that is determined by their rank relative to the zero base criterion. The number of panel tests performed and averaged represents a significant difference in the flexibility in which about 0.2 PSU is subjectively perceived.

D. Measuring the Strength of Tissue Paper

Tensile degree in dry state

Tensile strength is 2.54 cm wide strips using the Swing-Albert Intelect II standard tensile test (Swing-Albert Instrument Corporation, Durton Road 10960, Philadelphia, 19154, Pennsylvania). Is determined. This method is intended to be used for paper finished products, reel samples, and raw materials.

Sample adjustment and manufacture

Before the tensile test, the paper sample to be tested should be adjusted according to Top Skin Method # T402OM-88. All plastic and paper board package materials should be carefully removed from the paper samples before testing. Paper samples should be adjusted for at least 2 hours at a relative humidity level of 48-52% at 22-24 ° C. All aspects of sample preparation and tensile testing should be limited to the constant temperature and humidity room.

In finished products, the damaged product is discarded. Thereafter, five strips are removed from the four available units (also called sheets), and one is stacked on top of the other to form a long stack as a through hole between the matched sheets. Sheets 1 and 3 are identified for machine tension measurement and sheets 2 and 4 are identified for lateral tension measurement. Alternatively, JDC-1-10 or JDC with safety cutouts from Swing-Albert Instrument Corporation, Durton Road 10960, Philadelphia, 19154, Pennsylvania, to create four separate filing fees. -1-12) to cut through hole line. Stack 1 and Stack 3 are still identified for the machine tension test and Stack 2 and Stack 4 are identified for the transverse test. Two 2.54 cm wide strips are cut from the stack 1 and stack 3 in the machine direction. Two 2.54 cm wide strips are cut transversely from stacks 2 and 4. There are now four 2.54 cm wide strips for the machine tension test and four 2.54 cm wide strips for the lateral tension test. For finished product samples, eight 2.54 cm wide strips are available 5 unit (also referred to as sheet) thicknesses.

For raw and / or reel samples, a 38.1 cm x 38.1 cm (15 in x 15 in) size of 8 layers thick from the portion of interest of the sample was measured using a paper cutter (19154, Pennsylvania, Philadelphia, Durton Road 10960). Cut using a JDC-1-10 or JDC-1-12 with a safety shut-off device from Swing-Albert Instrument Corporation. Note that one 38.1 cm cut must be performed in a direction parallel to the machine direction and the other 38.1 cm cut must be performed in a direction parallel to the transverse direction. Paper samples should be adjusted for at least 2 hours at a relative humidity level of 48-52% at 22-24 ° C. All aspects of sample preparation and tensile testing should be performed confined to a constant temperature and humidity room.

From this 8-ply pre-regulated sample of 38.1 cm by 38.1 cm, four 2.54 cm by 17.78 cm (1 in by 7 in) strips are cut, with the long 17.78 cm side parallel to the machine direction. These samples are stored as machine direction reels or raw product samples. Cut another four 2.54 cm by 17.78 cm strips, with the long 17.78 cm side parallel to the transverse direction. These samples are stored as transverse reels or as raw sample material. All cuts have already been cut using a paper cutter (JDC-1-10 or JDC-1-12 with Swing-Albert Instrument Corporation's safety isolator, Duton Road 10960, 19154, Pennsylvania). Note that it was cut. There are now a total of eight samples: four of which are 8-ply 2.54cm × 17.78cm strips, 17.78cm side parallel to the machine direction, and four are 8-ply 2.54cm × 17.78cm As a strip of size, the 17.78 cm side is parallel to the transverse direction.

Operation of tensile testing machine

For a practical measurement of tensile strength, a Swing Albert Intelligent II Tensile Tester (Swing-Albert Instrument Corporation, Durton Road 10960, Philadelphia, 19154, Pennsylvania) is used. Insert a flat face clamp into the device and calibrate the tester according to the instructions given in the Operating Instructions of the Swing Albert Intelligent II. Set the instrument crosshead speed to 4.00 inches / minute and the first and second gauge lengths to 5.0 inches (2 inches). The burst sensitivity should be set to 20 g, sample width 2.54 cm, and sample thickness 0.064 cm (0.025 in).

The load cell is chosen such that the expected tensile strength for the sample results to be tested is between 25% and 75% of use. For example, a 5000g load cell may be used for a sample having an expected tensile range of 1250g (25% of 5000g) to 3750g (75% of 5000g). The tensile tester can be set in the 10% range of a 5000g load cell so that samples with expected tensile strengths of 125g to 375g can be tested.

Take one of the tension strips and place one end of it in one clamp of the tensile tester. The other end of the paper strip is placed in the other clamp. Note that the long side of the strip will be parallel to the side of the tester. Also note that the strips do not hang on either side of the two clamps. In addition, each pressure of the clamp must be in complete contact with the paper sample.

If the reset state is not performed automatically by the instrument, make the necessary adjustments to set the instrument clamp to its initial starting position. As mentioned above, the following paper strip is inserted into two clamps to obtain a tensile strength measurement in g. Tensile measurements are obtained from all paper test strips. It should be noted that during the test the reading should not be read if the strip slips or ruptures at the edge of the clamp.

Calculation

For four machine direction 2.54 cm wide finished strips, four individual recorded tensile measurements are combined. This sum is divided by the number of strips tested. This number should normally be four. In addition, divide the sum of the tensile strength values reported by the number of units available per tension strip. This is generally 5 for both single and double ply products.

Repeat the calculation for the transverse finished strip.

For raw machined or reel samples in the machine direction, four separately recorded tensile measurements are combined. Divide this sum by the number of strips tested. This number should normally be four. In addition, divide the sum of the tensile strength values reported by the number of units available per tension strip. This is generally eight.

This calculation is repeated for untranslated or reel sample paper strips.

All results are in g / in.

In this application, the tensile strength must be converted into 'specific total tensile strength', defined as the sum of tensile strengths measured in the machine and transverse directions and divided by the basis weight and corrected in meters.

Example 1

This example illustrates a method of making a two-ply bath tissue with uniform discontinuous deposits of substantially softened chemical softener using an offset roto-gravure printer.

Softeners used in the preparation of the softener solution are as follows:

1. Tallow diester chloride quaternary salt (ADOGEN SDMC), available from WITCO Chemical Company, Greenwich, Connecticut, USA.

2. Jay, Phillipsbury, New Jersey. tea. Polyethylene glycol 400 commercially available from J. T. Baker Company

3. Isostearic Acid (Century 1105), sold by Union Camp Company, Wayne, NJ.

A softener solution is prepared by melting 75% tallow diester chloride quaternary salt, 20% polyethylene glycol 400 and 5% isostearic acid in a constant temperature vessel maintained at 60 ° C. (140 ° F.) and then mixing. The softener solution is then fed to the grabber pan so that the softener solution fills the recessed area of the rotating grabber cylinder.

The Gravure cylinder structure includes a central void region suitable for circulating the heating fluid such that the surface of the roller is maintained at approximately 60 ° C. The surface of the gravure cylinder, in which the recessed area is engraved by the laser technique, is clad with aluminum oxide ceramic. The concave regions are hemispherical in shape, each of which has a diameter of about 400 μm and thus a depth of about 200 μm. The pattern of the concave region is hexagonal, and the frequency of the concave region is 10 per 2.54 cm in length (and thus 115 regions / in ² ). The percentage of total area protected by the concave area is about 2.2%.

Flexible PTFE doctor blades are used to blade excess softener solution from the surface of the grabber cylinder.

The offset printer operates so that the surface speed of the cylinder, i.e. the web speed, is 30.48 m / min (100 ft / min).

The Graveur cylinder operates in contact with the applicator cylinder. The applicator cylinder has a rubber cover with a hardness of 50 P & J. These two cylinders are loaded in the interface such that the width of the contact area of the two cylinders due to the deformation of the rubber cover on the applicator cylinder is 12.7 / 81.28 cm (5/32 inch). Thus, the softener solution moves from the grabber cylinder to the applicator cylinder.

The applicator cylinder is operated in close proximity to the printing cylinder. The printing cylinder is a steel structure. These cylinders are loaded and stopped so that there is a 13 mil gap between the two cylinders.

Through a gap formed between the applicator cylinder and the printing cylinder, a two-ply bath tissue paper web having a thickness of about 18 mils is passed through, where the softener solution moves from the applicator cylinder to the tissue paper web. The tissue paper with the gap formed by the applicator cylinder and the printing cylinder contains about 1.2% by weight of a uniformly fixed softener corresponding to the concave area of the grabber cylinder.

The resulting 2-ply tissue web is converted into a roll of bath tissue.

Example 2

This example illustrates a method of making a two-ply bath tissue with uniform discontinuous deposits of substantially softened chemical softener using an offset roto-gravure printer.

Softeners used in the preparation of the softener solution are as follows:

1. Tallow diester chloride quaternary salt (ADOGEN SDMC), available from WITCO Chemical Company, Greenwich, Connecticut, USA.

2. Jay, Phillipsbury, New Jersey. tea. Polyethylene glycol 400, commercially available from J. T. Baker Company

3. Isostearic acid (Century 1105), available from Union Camp Company, Wayne, NJ.

4. Amino polydimethylsiloxane (SF 1921, available from GE Silicones, Waterford, NY)

A softening solution is prepared by melting and mixing 33.8% tallow diester chloride quaternary salt, 9% polyethylene glycol 400, 2.3% isostearic acid and 55% SF1921 in a constant temperature vessel maintained at 60 ° C. The softener solution is then fed to the grabber pan so that the softener solution fills the recessed area of the rotating grabber cylinder.

The Gravure cylinder structure includes a central void region suitable for circulating the heating fluid such that the surface of the roller is maintained at approximately 60 ° C. The surface of the gravure cylinder, in which the recessed area is engraved by the laser technique, is clad with aluminum oxide ceramic. The concave regions are hemispherical in shape, each of which has a diameter of about 400 μm and thus a depth of about 200 μm. The pattern of the concave region is hexagonal, and the frequency of the concave region is 10 per 2.54 cm in length (and thus 115 area / in ² ). The percentage of total area protected by the concave area is about 2.2%.

Flexible PTFE doctor blades are used to blade excess softener solution from the surface of the grabber cylinder.

The offset printer is operated so that the surface speed of the cylinder, ie the web speed, is 30.48 m / min.

The Graveur cylinder operates in contact with the applicator cylinder. The applicator cylinder has a rubber cover with a hardness of 50 P & J. These two cylinders are loaded in the interface such that the width of the contact area of the two cylinders due to the deformation of the rubber cover on the applicator cylinder is 12.7 / 81.28 cm. Thus, the softener solution moves from the grabber cylinder to the applicator cylinder.

The applicator cylinder is operated in close proximity to the printing cylinder. The printing cylinder is a steel structure. These cylinders are loaded and stopped so that there is a 13 mil gap between the two cylinders.

Through a gap formed between the applicator cylinder and the printing cylinder, a two-ply bath tissue paper web having a thickness of about 18 mils is passed through, where the softener solution moves from the applicator cylinder to the tissue paper web. The tissue paper, with the gap formed by the applicator cylinder and the printing cylinder, contains about 1.5% by weight of a uniformly fixed softener corresponding to the concave area of the grabber cylinder.

The resulting 2-ply tissue web is converted into a roll of bath tissue.

Example 3

This example illustrates a method of making a two-ply bath tissue with uniform discontinuous deposits of substantially softened chemical softener using an offset roto-gravure printer.

Softeners used in the preparation of the softener solution are as follows:

1. Tallow diester chloride quaternary salt (ADOGEN SDMC), available from WITCO Chemical Company, Greenwich, Connecticut, USA.

2. Jay, Phillipsbury, New Jersey. tea. Polyethylene glycol 400 commercially available from J. T. Baker Company

3. Isostearic Acid (Century 1105), sold by Union Camp Company, Wayne, NJ.

A softener solution is prepared by melting 76% tallow diester chloride quaternary salt, 20% polyethylene glycol 400 and 4% isostearic acid in a constant temperature vessel maintained at 60 ° C. and then mixing. The softener solution is then fed to the grabber pan so that the softener solution fills the recessed area of the rotating grabber cylinder.

The Gravure cylinder structure includes a central void region suitable for circulating the heating fluid such that the surface of the roller is maintained at approximately 60 ° C. The surface of the gravure cylinder, in which the recessed area is engraved by the laser technique, is clad with aluminum oxide ceramic. The concave regions are hemispherical in shape, each of which has a diameter of about 400 μm and thus a depth of about 200 μm. The frequency of the concave area is 10 per 2.54 cm (and therefore 115 area / in ² ). The percentage of total area protected by the concave area is about 2.2%.

Flexible PTFE doctor blades are used to blade excess softener solution from the surface of the grabber cylinder.

The offset printer is operated so that the surface speed of the cylinder, ie the web speed, is 30.48 m / min.

The Graveur cylinder operates in contact with the applicator cylinder. The applicator cylinder has a rubber cover with a hardness of 50 P & J. These two cylinders are loaded in the interface such that the width of the contact area of the two cylinders due to the deformation of the rubber cover on the applicator cylinder is 12.7 / 81.28 cm. Thus, the softener solution moves from the grabber cylinder to the applicator cylinder.

The applicator cylinder is operated in close proximity to the printing cylinder. The printing cylinder is a steel structure. These cylinders are loaded and stopped so that there is a 15 mil gap between the two cylinders.

Through a gap formed between the applicator cylinder and the printing cylinder, a two-ply bath tissue paper web having a thickness of about 18 mils is passed through, where the softener solution moves from the applicator cylinder to the tissue paper web. The tissue paper, in which the gap formed by the applicator cylinder and the printing cylinder, is present, contains about 0.7% by weight of a uniformly fixed softener corresponding to the concave area of the grabber cylinder.

The resulting two-ply bath tissue paper web is molded on a roll and passed through the printing operation once again in the same manner. At the second pass, the tissue is oriented so that some softener is applied to the unprinted surface at the first pass. The tissue paper, with the gap formed by the applicator cylinder and the printing cylinder, contains a total of about 1.3% by weight of a uniformly fixed softener corresponding to the concave area of the grabber cylinder.

The resulting 2-ply tissue web is converted into a roll of bath tissue.

The essential properties of the resulting tissue are measured and the flexibility is compared with the product made without printing the same starting tissue.

Example 1 Example 2 Example 3

Softener Content (%) 1.2% 1.5% 1.4%

Caliper (mil) 17.4 17.5 11.1

Tensile Strength (m) 360 380 400

Flexibility Points +0.9 +0.8 +1.7

Claims (11)

At least one outer surface has a uniform discontinuous surface deposit of a chemical softener fixed, wherein the surface deposits are spaced at a frequency of 5 to 100 regions per 1 inch (2.54 cm) in length, and the chemical softener is quaternary Soft tissue paper products containing one or more layers of ammonium compounds. The method of claim 1, Tissue paper wherein the chemical softener has the formula Formula 1 _{(R 1) 4-m -} N + - [R 2] m X - Where m is 1 to 3; R ₁ is each C ₁ -C ₆ alkyl or alkenyl group, hydroxyalkyl group, hydrocarbyl or substituted hydrocarbyl group, alkoxylated group, benzyl group or mixtures thereof; R ₂ is a C ₁₄ -C ₂₂ alkyl or alkenyl group, hydroxyalkyl group, hydrocarbyl or substituted hydrocarbyl group, alkoxylated group, benzyl group or mixtures thereof; X ^_ is a certain softener-miscible anion. The method of claim 1, The tissue wherein the chemical softener has the formula (2): Formula 2 (R ₁ ) _4-m -N ⁺ -[(CH ₂ ) _n -Y -R ₃ ] _m X ^_ Where Y is -O- (O) C-, -C (O) -O-, -NH-C (O)-or -C (O) -NH-; m is 1 to 3; n is 0 to 4; R ₁ is each C ₁ -C ₆ alkyl or alkenyl group, hydroxyalkyl group, hydrocarbyl or substituted hydrocarbyl group, alkoxylated group, benzyl group or mixtures thereof; R ₃ is a C ₁₃ -C ₂₁ alkyl or alkenyl group, hydroxyalkyl group, hydrocarbyl or substituted hydrocarbyl group, alkoxylated group, benzyl group or a mixture thereof; X ^_ is a certain softener-miscible anion. The method according to any one of claims 1 to 3, Tissue paper wherein the chemical softener further comprises a polyhydroxy compound and a fatty acid. The method of claim 4, wherein The polyhydroxy compound is selected from the group consisting of polyethylene glycol, polypropylene glycol and mixtures thereof; Tissue paper wherein the fatty acid comprises a C ₆ -C ₂₃ linear or branched saturated or unsaturated analog. The method of claim 1, Tissue paper wherein the chemical softener comprises a polysiloxane compound. The method of claim 2 or 3, Tissue paper wherein the chemical softener further comprises a polysiloxane compound. The method according to any one of claims 1 to 3, Tissue paper with a dense pattern of paper. The method according to any one of claims 1 to 3, Tissue paper in which the paper is a non-creped, aeration-dried paper. delete The method according to any one of claims 1 to 3, Tissue paper wherein the chemical softener comprises from 0.1% to 10% by weight of the paper.